TY - JOUR A1 - Noyalet, Laurent A1 - Ilgen, Lukas A1 - Bürklein, Miriam A1 - Shehata-Dieler, Wafaa A1 - Taeger, Johannes A1 - Hagen, Rudolf A1 - Neun, Tilmann A1 - Zabler, Simon A1 - Althoff, Daniel A1 - Rak, Kristen T1 - Vestibular aqueduct morphology and Meniere’s disease - development of the vestibular aqueduct score by 3D analysis JF - Frontiers in Surgery N2 - Improved radiological examinations with newly developed 3D models may increase understanding of Meniere's disease (MD). The morphology and course of the vestibular aqueduct (VA) in the temporal bone might be related to the severity of MD. The presented study explored, if the VA of MD and non-MD patients can be grouped relative to its angle to the semicircular canals (SCC) and length using a 3D model. Scans of temporal bone specimens (TBS) were performed using micro-CT and micro flat panel volume computed tomography (mfpVCT). Furthermore, scans were carried out in patients and TBS by computed tomography (CT). The angle between the VA and the three SCC, as well as the length of the VA were measured. From these data, a 3D model was constructed to develop the vestibular aqueduct score (VAS). Using different imaging modalities it was demonstrated that angle measurements of the VA are reliable and can be effectively used for detailed diagnostic investigation. To test the clinical relevance, the VAS was applied on MD and on non-MD patients. Length and angle values from MD patients differed from non-MD patients. In MD patients, significantly higher numbers of VAs could be assigned to a distinct group of the VAS. In addition, it was tested, whether the outcome of a treatment option for MD can be correlated to the VAS. KW - vestibular aqueduct (VA) KW - 3D analysis KW - temporal bone KW - saccotomy KW - computed tomography KW - Meniere’s disease Y1 - 2022 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-312893 SN - 2296-875X VL - 9 ER - TY - JOUR A1 - Müller-Graff, Franz-Tassilo A1 - Ilgen, Lukas A1 - Schendzielorz, Philipp A1 - Voelker, Johannes A1 - Taeger, Johannes A1 - Kurz, Anja A1 - Hagen, Rudolf A1 - Neun, Tilmann A1 - Rak, Kristen T1 - Implementation of secondary reconstructions of flat-panel volume computed tomography (fpVCT) and otological planning software for anatomically based cochlear implantation JF - European Archives of Oto-Rhino-Laryngology N2 - Purpose For further improvements in cochlear implantation, the measurement of the cochlear duct length (CDL) and the determination of the electrode contact position (ECP) are increasingly in the focus of clinical research. Usually, these items were investigated by multislice computed tomography (MSCT). The determination of ECP was only possible by research programs so far. Flat-panel volume computed tomography (fpVCT) and its secondary reconstructions (fpVCT\(_{SECO}\)) allow for high spatial resolution for the visualization of the temporal bone structures. Using a newly developed surgical planning software that enables the evaluation of CDL and the determination of postoperative ECP, this study aimed to investigate the combination of fpVCT and otological planning software to improve the implementation of an anatomically based cochlear implantation. Methods Cochlear measurements were performed utilizing surgical planning software in imaging data (MSCT, fpVCT and fpVCT\(_{SECO}\)) of patients with and without implanted electrodes. Results Measurement of the CDL by the use of an otological planning software was highly reliable using fpVCT\(_{SECO}\) with a lower variance between the respective measurements compared to MSCT. The determination of the inter-electrode-distance (IED) between the ECP was improved in fpVCT\(_{SECO}\) compared to MSCT. Conclusion The combination of fpVCT\(_{SECO}\) and otological planning software permits a simplified and more reliable analysis of the cochlea in the pre- and postoperative setting. The combination of both systems will enable further progress in the development of an anatomically based cochlear implantation. KW - interelectrode-distance KW - Cochlear duct length KW - Cochlear planning software KW - fpVCT KW - secondary reconstruction KW - MSCT Y1 - 2022 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-266798 SN - 1434-4726 VL - 279 IS - 5 ER - TY - THES A1 - Ilgen, Lukas T1 - Ermittlung cochleärer Längen- und Winkelmaße mittels Flachdetektor-Volumen-Computertomographie - Evaluation der Anwendung sekundärer Rekonstruktionen T1 - Analysis of the cochlear duct and angular length by flat-panel volume computed tomography - Evaluation of the use of secondary reconstructions N2 - Für die Cochlea-Implantat-Versorgung ist die Kenntnis der individuellen Anatomie der Hörschnecke im perioperativen Kontext essenziell, um ein suffizientes audiologisches Resultat sicherzustellen. Ein akkurates Verfahren hierfür stellt die 3D multiplanare Rekonstruktion (3D-curved MPR) in Schnittbildgebung dar. Notwendige Voraussetzung ist jedoch eine hinreichende Bildqualität. In dieser Arbeit wurde das Augenmerk auf die sekundäre Rekonstruktion von Primärdatensätzen der Flachdetektor-Volumen-Computertomographie (fpVCTSECO) gerichtet. Diese bietet nämlich die Möglichkeit, die Bildqualität zu steigern, ohne jedoch eine als kritisch einzuschätzende Dosissteigerung in Kauf nehmen zu müssen. Es konnte gezeigt werden, dass es für die Messung der Länge von 2 Schneckenwindungen (2TL), der gesamten cochleären Länge (CDL) und dem Winkelmaß (AL) mittels 3D-curved MPR in der fpVCT keinen signifikanten Unterschied gegenüber der Mehrschicht-CT gibt. In beiden Modalitäten wurden alle drei Parameter gegenüber der Referenzbildgebung micro-CT deutlich unterschätzt. Durch die fpVCTSECO war es möglich, die Genauigkeit der Messungen zu steigern und den Werten der Referenz anzunähern. Lediglich für AL muss eine geringfügige systematische Unterschätzung beachtet werden. Postoperativ zeigte sich mit einliegendem Elektrodenträger für 2TL eine ebenso präzise Messung wie präoperativ ohne. Jedoch wurde die CDL um circa 0,5 - 0,7 mm unterschätzt. Ursächlich hierfür dürften vor allem Metallartefakte gewesen sein. Auch wenn die 3D-curved MPR in Kombination mit der fpVCTSECO postoperativ zur Visualisierung der räumlichen Beziehung von Elektrodenträger, Modiolus und ossärer lateraler Wand sehr gut geeignet war, so muss sich der Einfluss dieser Diskrepanz für die audiologische Anpassung in Zukunft erst noch zeigen. N2 - Knowledge of the individual anatomy of the cochlea is essential for optimal hearing perception outcomes in cochlear implantation. 3D-curved multiplanar reconstruction (3D-curved MPR) in cross-sectional imaging is a very precise method. But for this purpose, high-resolution quality is an indispensable requirement. In this study, special attention was turned to secondary reconstruction of primary data of flat-panel volume computed tomography (fpVCTSECO). This postprocessing application provides an opportunity to increase image quality. Beneficially, there is no need of applying additional radiation dose, which should always be regarded critically. For the cochlear duct length (CDL), the two-turn length (2TL) and the angular length (AL), there were no statistically significant differences between fpVCT and multislice computed tomography applying 3D-curved MPR. In contrast to reference imaging modality micro-CT, a clinically relevant underestimation of all three parameters was evident. Using fpVCTSECO, precision of measurements could be increased significantly. It was possible to reach the accuracy of the reference. Only concerning AL, a slight and systematic underestimation must be considered. Postoperatively, after insertion of the electrode into the cochlea, measurement of 2TL was as precise as the preoperative one. For CDL, an underestimation of approximately 0.5 - 0.7 mm was evident. Most likely, this fact was linked to postoperative metal artifacts. Even though 3D-curved MPR in combination with fpVCTSECO is a great possibility to visualize the spatial relation of electrode, modiolus and bony lateral wall, the influence of this difference on audiological fitting procedures has still to be investigated in future studies. KW - Cochlea KW - Anatomie KW - Computertomografie KW - Cochlear-Implantat KW - Dreidimensionale Rekonstruktion KW - cochlear duct length KW - CDL KW - MSCT KW - fpVCT KW - CI Y1 - 2023 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-327945 ER -